A drive unit changes an irradiation direction of irradiation light from a light-emitting portion. A setting unit sets the irradiation direction of the irradiation light from the light-emitting portion. A control unit controls the drive unit. Depending on a cause of which the irradiation direction of the irradiation light from the light-emitting portion changes from the irradiation direction that is set by the setting unit, the control unit changes responsiveness of the drive unit that changes the irradiation direction of the irradiation light from the light-emitting portion into the irradiation direction that is set by the setting unit.

The present invention relates to a lighting control device, the device comprising means for receiving a trigger; and means for switching operation of a lighting device from a continuous mode to a flash mode upon receipt of said trigger; wherein said lighting device comprises at least one light emitting diode; and said flash mode is at a higher brightness than said continuous mode. The invention also relates to a lighting system comprising: a lighting device comprising at least one light emitting diode; and a lighting control device; wherein the lighting control device is operable to switch operation of said lighting device between a continuous mode and a flash mode; wherein the flash is at a higher brightness than said continuous mode.

The present invention relates to a lighting control device, the device comprising means for receiving a trigger; and means for switching operation of a lighting device from a continuous mode to a flash mode upon receipt of said trigger; wherein said lighting device comprises at least one light emitting diode; and said flash mode is at a higher brightness than said continuous mode. The invention also relates to a lighting system comprising: a lighting device comprising at least one light emitting diode; and a lighting control device; wherein the lighting control device is operable to switch operation of said lighting device between a continuous mode and a flash mode; wherein the flash is at a higher brightness than said continuous mode.

A method for generating a headshot can include (i) arranging a diffuse light system by positing a first light source to emit light toward a scattering layer including a white surface such that the emitted light reflects diffusely off of the scattering layer, (ii) positioning a background layer made of translucent material such that diffuse light from the diffuse light system at least partially transmits through the background layer, wherein the background layer has disposed thereon a bokeh background image, and wherein the bokeh background image is illuminated by the diffuse light, (iii) arranging a subject lighting system to illuminate a subject positioned proximate to the background layer, and (iv) capturing a photograph of at least a portion of the subject and the bokeh background image with a camera.

A method for generating a headshot can include (i) arranging a diffuse light system by positing a first light source to emit light toward a scattering layer including a white surface such that the emitted light reflects diffusely off of the scattering layer, (ii) positioning a background layer made of translucent material such that diffuse light from the diffuse light system at least partially transmits through the background layer, wherein the background layer has disposed thereon a bokeh background image, and wherein the bokeh background image is illuminated by the diffuse light, (iii) arranging a subject lighting system to illuminate a subject positioned proximate to the background layer, and (iv) capturing a photograph of at least a portion of the subject and the bokeh background image with a camera.

An image capturing device includes a camera unit and a casing enclosing the camera unit. The camera unit includes an optical lens and an image sensing module. The casing includes a first housing body, a second housing body attachable to the first housing body, a front enclosure, and a back enclosure. The first housing body, the second housing body, the front enclosure, and the back enclosure jointly enclose a receiving space. A first ventilating window is disposed on the first housing body or the second housing body, and a second ventilation window is disposed on the back enclosure. The first ventilating window and the second ventilation window are configured to provide ventilation to the receiving space.

An image capturing device includes a camera unit and a casing enclosing the camera unit. The camera unit includes an optical lens and an image sensing module. The casing includes a first housing body, a second housing body attachable to the first housing body, a front enclosure, and a back enclosure. The first housing body, the second housing body, the front enclosure, and the back enclosure jointly enclose a receiving space. A first ventilating window is disposed on the first housing body or the second housing body, and a second ventilation window is disposed on the back enclosure. The first ventilating window and the second ventilation window are configured to provide ventilation to the receiving space.

Provided is an imaging system capable of acquiring images that favorably show the situation in a mobile object seen through a window regardless of the height of a passing mobile object. The imaging device 3 images a mobile object. The first lighting device 1 irradiates the mobile object with light. The second lighting device 2 is installed at a position higher than the first lighting device 1 and irradiates the mobile object with light. The control unit 4 causes the first lighting device 1 and the second lighting device 2 to emit light in respective patterns while the imaging device 3 is imaging a mobile object over a plurality of frames. The selector 5 selects images acquired by imaging a mobile object irradiated with light in a preset manner depending on the height of the mobile object from among images for a plurality of frames.

Provided is an imaging system capable of acquiring images that favorably show the situation in a mobile object seen through a window regardless of the height of a passing mobile object. The imaging device 3 images a mobile object. The first lighting device 1 irradiates the mobile object with light. The second lighting device 2 is installed at a position higher than the first lighting device 1 and irradiates the mobile object with light. The control unit 4 causes the first lighting device 1 and the second lighting device 2 to emit light in respective patterns while the imaging device 3 is imaging a mobile object over a plurality of frames. The selector 5 selects images acquired by imaging a mobile object irradiated with light in a preset manner depending on the height of the mobile object from among images for a plurality of frames.

The application provides a shooting device with slide rails, comprising a support component, a tabletop arranged on the support component, a display screen arranged on one side of the tabletop, and a shooting rotational station arranged on the other side of the tabletop; a fill light arranged between the shooting rotational station and the tabletop; a slide rail component used for loading the shooting rotational station and the fill light, and a rotating component installed on the support component; the rotating component is rotatably installed on the support component, the display screen is arranged on one end of the rotating component, the slide rail component is arranged on the other end of the rotating component, the shooting rotational station and the fill light are slidably installed on the slide rail component, and the slide rail component is flippable relative to the rotating component.